Crucible charger



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Nov. 17, 1925- G. E. MARLA'T-r CRUCIBLE CHARGER Filred Aug. 8`1922 6 Sheets-Sheet 2 Nov. ,17 1925- G. E. MARLAT-r CRUCIBLE CHARGER Fi'le-djug. 8; 1922 6 Sheets-Sheet 3 Nov. 17. 1925' ,6. E.. MARLATT cnuclns cansan' rund Aub 8. 192i 6 4Sheet-s--Shnt 4 l o w mf W W,.f/ 0 l uw ma ../J l w no l .y of n f f 7 f n. 5 y ZJ d 7 z o 0 J fw v n,

Novo

G. E'. MARLATT cnucILf: camina Patented N ov. 17, 1925.`

-l-.GnoRGE E. MARLATT,- .oF PASADENA. AL'IQRNIA.

" CRUCIBL'E ci-'RGER.

Application filed4 August 8,' '1922:Seria1Nof580,448.

T 'all whom z'fmag/ concern@ Be it known'that- I;-GEoRG1iEMARLATT5 a citizeny of the IUnitedfStates,-'residing at Pasadena, in the-county'- of Los xAngeles and State of California;-have'finvented newfa'nd useful Improvements in Crucible''Glntrgers7 of which the-folloivingY is a specification. n Myinventionrelates toi'aneans for 'autoniatiea-lly l'replen-ish-ing lthe##"n'ielting-`-pots from which l' the--1n-'aterial 'for type type- Slugs" or'fother: products-is puinped-,poured ori otherwise .witlidi'aivn-t'o forni* the product, the particular 'fil-lilstiration5 anddescription thereof being in 'connectionwith slug- Casting machines ofv the "linotype class.

ln `connection with 'such-1inachinesfithe niainpurpose ofrtiny invention` isftoequal or surpass the ybest possi-blepracticesof a careful operator orf attendanti notY -only'- in supplying feed'fnietalv to' the melting-pot at regular `intervals vv underi l normal A'operating conditions-,- but also to automatically Aretard vor advance the supply under -varyifngfeonditions inI order 13o/maintain the-'teinp'erature of the molten unetal' at lthe pointy best suited --for producing var`fingsizes-1E ofslugs fat varying' speeds 0fproduction.

f Another purpose 1s torenderthe-potfcharger capable of feedingto' Vthe ICrucible inetalzyin various "shapes 'such as fstandardifsize pigs-y slugs in `miscellaneous sizes,an'd largeingots." Minor and Icontributi-ng purposes willy be setforth in the subjoined Y specifications vand'fdescrip` tion of the accompanying'drawingsin which f Figure l is ar` side elevfation of thefprlncipal nortion of a l'slug-castinggg-l machine of the linotype class, showing Inv-)device intoperative position relative tl-ie'retof-and containing pigs Aof metal #for'.rep'lenishingthe nielting pot.

Fig. 2 shows a'-inod-iied forni of a-noti fying device includ'edfin Fig.- l.

Fig. 3' is a zView siinilarl to Fig. l,-sh`ow ing the feeder in'f'horizontal'position :and containing loose slugs of feed-metal forreplenishing the Crucible.

Fig. tis a front-end'lviewofithelfeeder as it appears-in 'Figi' 3. e

Fig. 5 showsA a follower andp'u'sher'. device applicable incertain fuses offlthe' feeder.

` Fig. 6 is aperspective viewfo'fJ an operating 'lever and parts carriedtliereby.

Fig. 7 shows the constructioirof-a-pot lid designedtcl break the" fallof the feed l metal and to fau'ton'iat-ically fcloseftheufpot opening 'a'lfter 'each replenishment f of 1 "the ypot crucible. f i Figs 8 is a-'fview1s`-i1nilar to4Fig'. lyshoWi-ng the feeder 1 in :use fin connection4 with. agigas torch as a prel'ieater'iforf@the :feecl inetal.- This? fviewfalso .shows the iusual: smallfp-igs offmetal fdi's'place'difbjfa aisingl'ef largeiingot. lThe viewffalso-:shows a :-coinbinediztemperature andi quantity-` regulatorffor v .the pot con# Etents. 1 Fig.,` 9-lshows adetai-lfron Figf.

-5-Fig; l0 is'. af fraginentary y '-vi'ewg'fpartlyin section',".of :the `combined feed' controloamd temperature#controldevice. i' 5 Fig. lOfshows afniodiliedf formf'of quantity# regulator forfethefv y'potf contents. v HUF-ig.y llwis ay viewlY ofthe'feederfcdiffering *from the'showing` of Fig. l8:.onlyl in' the fact 'that .the preheater is' of-'-el'ectricztype. Fig-.f 12 shows the fe-edecontrol-y feature-of .this present Linvention'zf applied" to an? earlier vvcontrol lfeature applicable to the ifeeder "shoWninF'Figs/.1, V'fand 8.

@linotypeniachine fFig.- :16 isv a fragmentary' view vfrom :the front 0f-r a` linotyp'e niachine',l showing V-the ineltin'gv potin :transversesection -o`n thf-line l-16 -16 offFig. l5,v and includes-'the usual automatic stopping y devices; under control 'of' which Aflies feeder *and* melting-pot are brought --incertain jabnor-in al circumstances'. *In its function asa vteinpeiaturefregulator 'thisVl replenisher Ltakes intoy considerati on 'the perinis'siblei range of inetal f content i in 'fthe Crucible and' the'periiiissible range' of temperature of the molten metal Therefore, preliminaryl to a'description ofthe feeder, the following explanation Y offthe usualf conditions `,and 'practices` favorable.' to: the-pro duc-tionof good vtype-'slugs-'lis givento serve as 'alb'asis ffors'an f' understanding? ofv 'the' 1 description of the '-feeder 'andi its operation.. `The temperature l of the in'olten Y metal inay range "froinlo F." to "550o vrF .;-the'- 'higher temperature'- being favorable to the-f productionoff-small 'slugs and the lower temperay mal or ture favorable to the production of large slugs. The proper temperature is presumed to be maintained by the usual automatic gas or electric current regulator subject to such adjustment as an operator may malte in changing for quantity production as between large and small slugs. rllherefore, this invention is not concerned with the usual temperature range but rather with a departure therefrom due to failure of the usual regulator to function or because an operator misjudges the requisite temperature. ln this connection7 it may be noted that although a large slug requires a lowered temperature, nevertheless 'quantity production of large slugs would require a greater flow of gas (or electric current, if used) than quantity production of small slugs, due to the fact that the metal content in the Crucible is more rapidly depleted and replaced in casting large slugs. |Therefore the customary procedure would be to reduce the gas supply temporarily when changing to a large slug, especially if the temperature was above 5500 F., in order to reduce the temperature of the metal, and then to increase the gas .supply as production proceeded, in order to maintain the temperature. Regardless of the size of slug being cast, a large amount of molten metal in the crucible may permissibly he somewhat cooler than a smaller amount. This is because of the fact that if the metal is high in the pot and the temperature norlow when a shift is made from a small to a large slug, then production may continue for a longer time than if the metal were low and the temperature low, the partially-filled pot being chilled more rapidly than a full pot by the addition of cold feedmetal. A. pot barely full enough and barely hot enough to produce good small slugs would not produce good large slugs, for the reason that the larger mold cell would not receive enough metal from the low pot to displace the air in the mold, resulting in a porous slug; and, because of the distance between the surface of the metal in the pot throat 62 and the mold cell 60, plus the air condition noted, the metal would be cooled before and while entering the mold, producing a chilled slug. l3nt if the pot were normally full and the temperature high or even normal when shifting from a small slug to a large one, the face of the slug would be good, and sufficient air would be displaced from the mold, yet the slug would be porous or hollow for the reason that the large amount of hot metal in the mold would leak out of the usual air vents (not shown) before being sufficiently chilled by contact with the mold walls. Hence, the temperature of the metal should ideally be somewhat lower for a large slug than for a small one, and the potfull in order to best maintain' the lowered temperature. ln shifting resume from a large to a small slug the above-stated conditions and requirements would be reversed.

The usual linotype pot will hold about 40 pounds of metal, and under favorable conditions about one-third of this quantity may be withdrawn withoutdeleteriously affecting the slugs being cast. This one-third represents a range between the top of the plungerl well 90 and a rin@ 90 near the rim of the crucible. Therefore a favorable height for the molten metal would be a point midway between the top of the well and the ring. `With the metal at this midway height the temperature could be reduced by merely adding cold metal, and it could be raised either by pouring in preheated metal (if available) from another pot, or by delaying replenishing the pot until the quantity of metal has been reduced to a would still produce good slugs. Standard size pigs of linotype meta-l weigh about 21/2 gounds, equaling about 16 to a full Crucible. Therefore, with the surface of the metal slightly below the midway point above mentioned, three pigs may be added at one time or in close succession without danger of overflowing the crucible. An operator producing small (news) slugs will use one pig about every l5 minutes and when producing large (book) slugs will use a pig about every 5 minutes. Hence, taking 10 minutes as the average, after an operator had deposited three cold pigs at one time, 30 minutes could elapse before the metal had receded to the midway point, and 60 minutes before it had receded to the lowest permissible point. lt will be apparent that the temperature may be regulated to a large extent without changing the adjustment of the usual heatgovernor. A single co-ld pig will lower the temperature about 10o F. Therefore, if an operator had maintained the height of the metal at the midway point, but by reason of the machine standing idle or from other cause the temperature of the metal had risen above 5500 F., he could, before starting to cast large slugs, reduce the temperature to about 535 F. by adding several cold pigs; and thereafter the same volume of gas which had maintained the higher temperature for small slugs would maintain the lower teinperature for large slugs. The conditions and requirements may therefore be summarized as follows:

A low pot with a high temperature is the working equivalent of a high pot with a low temperature.y provided small slugs are being produced, but for large slugs the low pot would lea-ve too much air in the throat and mold to permit the plunger 89 to force the larger quantity of molten metal into the mold cell.

A pot that is full and barely hot enough for large 'slugs would not be hot enough for point which small slugs, for the reason that a larger' vproportion'of the metal content -offthe .small slug comes'in'contact with the walls'of the mold, Atending to chill the metal before it enters ythe character r'cavities of the linatrices 56.

-A pot that isl fullfand coolfenough for small. slugs might be too hot for large slugs, for vthe-reason that the larger quantity of metal would not cool .quickly enough .in the large moldl cell to prevent its'partial escape with the air through Athe air vents (not shown).

A pot that is low and barely hot enough to produce good small slugs might produce equally good large slugs for a limited time,lbut theaddition of'coldmetal to replaceithe increased consumption for the enlarged slug would soon chill the metal, producing a slug with a poor face.

With the pot mouth 58 properly heated vandprOperly vented for the escape of air fromy the-mold, a medium full; pot at a Vniedium temperature will ordinarily serve for either large or small slugs, provided the pot is replenished at regular intervals to compensate for consumption of metal, and provided further that? the usual temperature regulator is functioning properly.

.ltwillwbe apparent `that any ideal general use temperature lies aboutv midway between the ymaximum permissible for producing goodsmall lugsv andy the minimum permissible for producing good large slugs; that suoli a teniperatureis best maintained by replenishing the pot at regular intervals, and that any departure from such a temperature may be bestpreventedif'the metal in the pot is at afmedium height sov that the amount Ymaybe increased or diminished temporarily.

Grdinarily, ani'op'erator could not anticivpate the need of yloweringy or raising the temperature, but' wouldwait until the necessity wasy indicated by the condition ofthe slugsfbeing cast; therefore, a 'delay would ensue, as yproduction of usable slugs would have to awaitthe regulation of the temperature and cooling of the overheated mold. A purpose of the mechanism to be described is te automatically feed cold metal to the cruci-r ble atvsuch intervals of time as will maintain a midway height of themetal provided the ten'iperature is correct; toautomatically advance the feeding of the metal when the temperature is too high; to automatically reduce the heat supply when the temperature remains too high'pwith the pot full;` and to either stop the feedr or feed-preheated metal whenl the temperature vis too low. Hence, such a feeder will follow'the best practices 'of an operator and will improve' on such pr etices byV automatically correcting a too high or too low temperature before the prod- -uct isfaffeeted.

vThe storage portionof the feeder consist-s 'the inverted channel 3.

of two t'feed screws 1, Qlfbetween which the 4feedrmetal is confined, and an'inverted channel 3 on which thehmetal is supported. .In the case of'pigs 4 of the usual shapes-each successive pig is'engaged by each successive helix ofthe screws. .The pitch of the screws is preferably determined by thesize ofthe pigs, with the .diameter about equal to the pitch, in which casev the inclination rvof* the thread is somewhat steeper than the' engaged edgeof the pigs when stacked as iny Fig. l, the discrepancy being in favor of lthe-easy movement of the screw thread'awayfrom the pigsv and in a direction which will not `tend to wedge the pigs against the support 8. The screws arefturned in opposite directions,

eing geared for the purpose by means of a gear on the right-,hand screw Landa similar gear 6 on the left-hand screw 2. At their rear ends the screws are vvsupported in brackets 7 secured to the support vbyfineans of bolts 8, 9. .At the forward endthe screws are supported in brackets 10 secured tothe support 3 by means ofbolts 11,' 12. These forward brackets are flared outwardly below the center of the feed screws iii-order that they may notinterfere ywhen the vmetal is fed in the form of loose slugs 13. f'VVhen loose slugs are to be fed ai trough 14 is inserted beneath the-feed screws, the shape of the trough in cross section beingsuch that the slugs will tend to gravitate toward 'its longitudinal center between,v the screws. The forward end ofthe trough isprovided withclearances 14 vfor engaging the yfront l brackets 10 and issuficiently short to permit of being so engaged after being inserted beneath the feed screws. When employed as a slug feeder a follower or chaser 15 ispl'aced ldescribed the `feeder proper-need not differ whether employed as al pig feeder, slug feeder or large ingot feeder.

Forward of its center the feeder is supported on a replacement extension of a shaft 17`known as the mold-cani lever-handle shaft, which occupies the same position on various linotype machines and is therefore well adapted tothe purpose of a support forthis feeder.V Pearwardly the feeder issupported on anupright 18 which displaces and serres in lieu of the'usual cap screw occupying the same position in the machinev frame. rhe

vupright 18 is bent to horizontal at itsupper end and' is braced from the forward' support 17 by means ef a channel 19 contained within r[he brace 19 is at their intersecting ends.

permanent in the sense that it need not be removed in order to remove or raise the feeder and is secured to the support 18 by means of a spacer 19 and pin 19 (Fig. 16). 'l he inverted channel 3 is provided with open latches 20, 21, the slant and weight of the feeder serving to keep the latches in engagement with the supporting shafts. The forward support 17 carries a prop 22 which folds into the channeled. brace 1S) when the feeder is in its lowered position, and is used as a support for the feeder when in its raised position as a slug feeder (Fig. rlhe prop 22 is provided with a notch 23 which engages a cross-bolt 24 carried by the inverted channel 3. rlhe bolt 24 is forward of the supporting shaft 17 so as to employ the weight of the feeder in keeping the rear latch 2O in engagement. with the rear support 13 when the feeder is in raised position. The right-hand feed screw 1 carries a ratchet having teeth about equal in number to the minimum number of slugs i3 contained .in a pig 4 as determined by the size of the largest slugs. ylhe ratchet 24 is intermittently engaged by a pawl 25 carried by the seco-nd link 26 of a cam-controlled lever rfhis lever 27 and its second link 2G are channel shaped, the one link fitting within the other rllhey interconnected and joined to the inverted channel 3 by means of the upper horizontal angle 23 of a yoke 30, the lower angle 2) of which joins the pawl 25 to the lever link 26. rl'he two links of the lever are so shaped at their adjoining ends as to limit the spacing of their outer ends one from the other, and are normally held so spaced by means of a spring 31. At one of its ends the spring 31 engages the lower angle of the yoke 30 and at its other end it engages a centrally pivoted secondary lever 32 which carries a cam roller 33. The spring 31 thus serves the two-fold purpose of keeping the two links of the cam-controlled lever normally in engagement and minimum spaced, and also of keeping the cam roller 33 seated between the sides of the lever 27 as determined by the engagement of the secondary lever 32 with seating notches 34 formed in the lever 27. A cam 35, comm-on to linotype machines and known as the second elevator cam, is employed for controlling the lever 27 and, through the connections described, turning` the feed screws 1, 2. lt sometimes happens that, for reasons with which this invention is notconeerned, the machine inclusive of he cam 35 is turned backward by hand. ln such an event the cam roller 33 would lie in the path of the second shoulder 36 on the cam and be an obstruction. lt is for this reason that the cam roller 33 is pivotally and resiliently mounted as explained. In the event of such an occurrence the cam roller would be forced partially around its pivot 37 and the periphery of the cam would pass through the space in the lever 27 vacated by the roller. l/Vith the cam again turned to normal and in the normal direction, the roller would be automatically seated by means of the spring 31.

lf, with the pawl 25 in engagement with the ratchet 24, any obstruction or unusual condition should prevent the turning of the feed screws 1, 2, then the spring 3l would stretch when the cam 35 engaged the roller 33. .ln such an event the increased separation of the ends of the links 26, 27 of the lever would cause a connecting rod 33 between the link 2G and a bell 39 on the relatively movable link 27 to sound the bell 39, thus notifying an operator or attendant of the abnormal condition. Simultaneously with the sounding of the bell, a member 40, one end of which is pivoted to the link 23 and the other held normally at rest beneath a shoulder 41 on the link 27, is raised by means of a spring 42 and its free end enters in front of the shoulder 41, thus holding the links of the lever in expanded relation and preventing a repetition of the sounding of the bell. vlilith the parts thus held the feeder is rendered inoperative regardless of the initial cause of its inoperativeness, and may await the convenience of the operator before receiving attention. As hereinafter ez;- plained, the fact of the feeder becoming en'ipty of feed metal would cause the bell to be sounded. itn optional method of notifying an operator of a condition suoli as described is illustrated in Fig. 1 and consists of an arm 43 secured to the inner end of the upper angle of the yoke 30. Normally, the yoke 30 will rise and fall with the arm 26 at each rotation of the cam 35. But the conditions causing the expansion of the lever will leave the arm 43 in its upper position with the notch 44 in the path of a pin 45 carried by a swinging member 46 pivoted by means of a screw 47 to the usual second elevator arm 48. lllhen the second elevator 43 descends under control of its cam e5, the pin will miss the notch 44 provided conditions are normal; otherwise the pin will seat in the notch, holding up the elevator until the full contour of the cam 35 has cleared the roller 49. At this point the second elevator, would normally, have descended and tripped a detent 50 as a condition for the continued rotation of the machine; but failure of the elevator arm to descend will cause the machine to stop, thus notifying the operator of an abnormal condition which must be remedied before operation of the machine may continue. The detent 50 is a link in a safety device system common to linotype machines and more fully explained hereinafter.

All the mechanism so far described functions in like manner whether the feeder contains pigs, slugs or-a single. largevingot of'feed metal.v lith thefeeder raised for use as aslug lfeeder thecam roller 83 would automatically assume a posit-ion relative to the cam, 35 .which would'cause the pawl 25 to function without special` adjustment, butv the armgl, ifemployed, would need to bef-adjusted accordingly when raising.. or lowering the. feeder, providedit was intended tov function, which would be a matter. of choice with. an operator. No damageiwould result to .the feeder. as a consequence of eliminating both. the bell .and arm 43, thesebeing merely .notifyingdevices The ca-m l en-` gages the rollerV 33 immediately upon commencementof each successive rotation of the inachi-ne,.hence the feeder. is operated priery to..the.f0rward movement of the vineltingpot toward .the mold '54.

= I'provide fourmethods for making and breakingthe connection between the. pawl 25.

and ratchet 24.' One-.method dependsupon the weight of .the Vmeltingpot. 51 Vas determined bythequantity of molten metalthereim; -a secondmethod depends on a float. controlled bythe varying. height of kthe metal in the pot regardless of the weight1 thereof; the vthird methodis a combination. of the lirst two, and :the fourth method is a float in a mercury. container,the float 4.making and .breaking theY feed-'control yconnection regardless ofthe varying weightv of the melting 'potaor the temperatureaof.the,V contents of the pot... Any onerofthese methodsmay be employed. regardlessn of whether, the feeder is suppliedwith ..pigs,` slugs or single ingots, but-for convenience in illustration different methodsfare. shown in connection with: different .usesof thefeeder. Inconnection .with melting pots which. are .not movable, only the float principle may be employed; nalinotype machines the meltingpot ispivotally.mounted-on `a shaft 52; prior to theiaction of the pump 53 for force ing-.metal ,into the 1nold.54,tlie mold carrier is movedY forward v.a (short` distance. rinto engagement with the matrix kline 56; next the potl is likewise moved forward by its cam y57' 'until Ythe vented mouthpiece. 58 throughwhichthe metal-passes, is in close Contact wit-hthe. mold 54, .whereupon the pumpi`r descendsnnder control of the pump cam vthforicing. the molten :metalinto ,the mola cellGO and against thematrix line 56; thus forming a printing slug. y The pot is balauced'to an .extent by the usual balance springl. r)This springis intended `tch-ave but littleeffect whenthe lpot `mouth is leavingthe molded followinga ca st, the. weight of the pot being utilized to breakthe sprue left by thefgate perforationsof the, mouthpiece` 58,. the sprue either beingpulledout of .the perforatiens orfbroken from. the slug n as the pot recedes, beingmsubsequently grnnnlied fronagjilgeslug, Hence. the usual balance spring 61 does not. bear the. fullY weightof the pot atfa'nytime, but permits" it Ito rest.- against the most reduced portion of its cam'?v whenthe machineisin normal position. In. order to utilize thevary.- inggweight tof the pot for controlling the operation oflthe feeder under description, I provide yan auxiliary balance spring 68, which may be in close proximity to theusual spring, as'shown, or in any other convenient' position.,V The tension of this spring may beV regulated by means of tension vadjusting nuts Get so thatiit will, in co-operaticn with' the usual spring, ,fully bear theweight of the pot 'and hold it away frornthe mostreduced portion of the cam ,'57 when the pot is less than full of metal. "When themetal inthe pot isat ymaximum height the cam roller 65 may bear lightly againstthe cam, but not necessarily so. The auxiliary `spring 63 lhas no eifectvwhen the pot is forward/against the mold or breaking awav therefrom7 its range-of actionbeingv limited by limiting nuts'G which -stopagainsta plate 67as the pot moves forward. The springtrod'S *.is guided yin the plate/67. At its upper end the rod 68bears yagainst a pl'ate69 rinter'- posedbetween theusual balance spring,Y 6l andy a lcap-.70 which connects the spring to the potlever. 71." As thus constructed when the pot is moved forward the auxiliary spring will support its weight only'until the. limiting-.nuts 66 contact withtheplate 67, whereupon-a gap will exist between the end of the spring rod 68 and the upper plate 69,*leaving the pot normallyV heavy in its forward position for the p urposestated.4 .A medium height for the*` metal in the Crucible having been determined,` the tensionxof the springis adjusted by means .of the nuts 64 t0 cause thepot-cam roller/65' to remain .a slight y.distance away from the camf57 "when the 4metal is at medium height. Under these conditions'a contact pin 72, movablewith thepot-,Lbears against a slingi which is connected by means of a rod 74 to the pawl 25.k The connectingrod'll lis adjusted for length by means of a turn-buckle 75 so that with. the met-al in the pot-normallyy high the pawl 25 will beheld out of engagement with theratchet QL As the pot becomes light following successivecasts'of. metal theree from,`the. pot. willy settle a greater distance away fromxits cam-.following each return fromfthe,mold,` and throughv the connections described `will .thereforeipermit the pa-wl 25 to engagevv the test-hof the ratchetQ/ytheref upon at each rotation ofthe machine vthe ratchet will ,be turned one;tooth, gradually advancing thepigs't untilt-he feed Yscrews have made-a complete rotation, when the foremost pigwill be freed from engagement with the feed .sere-ws andwillfdrop into the pot. The Weight-.of lthe pigthus freed 'will againfeveight ythe sniiei'entlyito cause .it

ico

to settle close to its cam, and the pawl 25 will accordingly be disengaged from the ratchet 24. The number of teeth in the ratchet 24 is immaterial provided it is less than the number (about 8) of largest slugs contained in a pig of metal, for otherwise the screws would not be turned fast enough to supply metal for such maximum size slugs. The stroke of the pawl 25 may be regulated by means of an adjusting screw 7G in the lever link 26 and stopped against the bolt 8, and the measurements .may be such that the screw may be adjusted to cause the pawl to engage only alternate teeth of the ratchet when unusually large slugs are to be cast in quantity. rlhe contact pin 72 is carried by an arm 77 mounted on an extension of the usual pot hinge pin 78. The arm and pin may be knurled and broached as shown, to render the arm positively adjusted in co-operation with the adjustments previously described, and a clamping screw 79 serves to additionally tighten the arm on the hinge pin. rlhe front end of the feeder floor is bent downward to form an apron 80 for supporting and guiding the feed metal as it is freed from the feed screws and approaches the pot opening. The pigs are prevented from possible tilting by a cross-bolt 81 supported by extensions of the brackets 10, the bolt being at a height to engage the upper ends of the pig as its lower end engages the apron 80. In order that the pigs may not enter the pot with too much force l provide a self-closing lid upon which they drop in entering the Crucible. This lid is preferably formed in two halves 82, 83 each of which is controlled by springs 84 which may be of such strength as to best control the weight of the pigs as they enter the pot. The lid halves are each provided with end ywalls 85, S6 so that when the lid is closed a pit or hopper is formed into which the pigs or slugs may drop with security, and yet permit the pot to be nor` .mally closed to confine the heat. The lid halves are each self hinged to a frame 87 encompassing the pot opening and terminating as hinge pins in the usual lugs 88, so that the lid may be opened manually and swung forward to provide ample access to the Crucible for the purpose of skimming the metal and cleaning the plunger 89. The rear walls 86 of the lid halves have their upper edges terminated beneath the frame wire 87, the frame thus limiting the distance to which the springs 84 may return the lid halves.

Unless cleaned at appropriate times, the plunger 89 will bind in the well 90, due to the accumulation of oxides and dross. lf the condition is not remedied in time the plunger is removed with difficulty, due to the fact that the heaviest accumulation of dross is near the top .of .the well, especially if the metal has been permitted to get low` This same condition will sometimes prevent the pot returning the full distance towards its cam, because of its weight being partially sustained by the fouled plunger. Since such a condition would defeat the purpose of the auxiliary balance spring G3 it is therefore a purpose of this invention to provide means whereby an operator may be notified of a fouled condition of the plunger. To this end I secure to the pot by means of a screw 91 an arm 92, and on the second elevator arm provide a pawl 93. Normally the pawl 93 will clear the end of the arm 92 when the elevator descends, permitting an abutment screw 94 to trip the detent 50 as a condition for the continued rotation of the machine. But if the pot remains forward by reason of a fouled plunger or an abnormally light pot, or from other cause, then the pawl 93 will engage the end of the arm 92 and the complete descent of the elevator arm will be hindered, resulting in the stopping of the machine as notice to the operator that an abnormal condition exists. lf preferred by an operator the sounding of a bell 95 (Fig. 2) may serve instead of actually stopping the machine, contact of the pawl 93 with the bell lever 90 causing the bell to sound. If the operator knows the cause of the bell sounding and the product is not adected, the condition may then await the convenience of the operator before being remedied, or an attendant may supply metal to the feeder or pot without disturbing the operator. A.

pawl spring 93 prevents any binding of the pawl during the return movement of the elevator arm. The detent 50 rises and falls in front of a projection 97 integral with the usual transfer slide 98 which is connected by means of a link 99 to an arm 100 secured to a shaft 101. At the rear of the supporting column 102 the shaft 101 is provided with an arm 103 and cam roller 104. A spring 105 normally keeps the roller 104 in engagement with its cam 106, anc the cam turns the roller 104 will cause a safety pawl 1.07 to be forced backward into a recess 108 in the cam 109. When thus operating normally the pawl 107 will miss a stopping lever 110 and the machine will complete its rotation, being finally stopped by a stopping pawl 111 coming to rest on the stopping lever 110 and disconnecting the clutch arms 112 from the clutch drum 113, 'all in the manner well known in the art. But if the detent 50 is not tripped to free the slide 98, then the roller 104 cannot engage the de pressions of its cam and the pawl 10iu will remain in the plane of the stopping lever 110 and will come to rest thereon, disconnecting the clutch arms from the clutch drum and stopping the machine. The abnormal condition causing the machine to be stopped having been remedied the slide 9S is then eased over manually, causingthee roller, 104 to knock tliepawl- 107jfioin the. stopping lever 110, whereupon the machine] will vcomplete itsrotation. VHence tlielusual safety devices -serveto. stoirtheinachine wheiitlie specified abnerinal ,conditions affectthe inetalpot or. feeder.. p

lThe ineans foradvancing, and retarding;A the .feed .of replenisghing` inetalis illustrated in Figs.` 8 and1O and, is an elaboration of the feed contiol'principle already described. Inthis .forni of'control-tlie contact for deteiii'iiiiin 3;.tlie .engagement and disengagement of the pawl 25 with the ratchet 24 is a pivotedf.n'ieinberp11e haring a sideshoiil-x der 115 for engaging'` the sling'lln.V The Contact edge ofthe sling ,is formed in three steps o. I), c The V.iniddle Step cO-operates with .the contacting;r slioiildeimll whenl the metal is noi-inalbotlr as Eto :height tand tein-l pei'ature.;,. thelower stepa` receives the contact when the .temperature is low or the metal is low erin the case of both conditions coinbinedfgthe upper. stepc is a clearance preventinga Contact when the temperature is high,l so that a maximum amount of cold iii-etal may Abe fed itoccool.y theipot'eontents. The pivot-ed arm 1111 is under direct control of a hollow inii-eizloat 117l buoyed in a .quantity of mercury 118'in a container bulb 119 and tube 120.y `With the metall- 121m th'epot at a niediuin heightvthe. bulb.,119 willbe partiallyiininersed therein and if the teinperature'; of themetal .is correct` (between lland 1509 F.) theinner'tio'at 117'w1ill holdtlie contact shoulder 1 1'5in front of the middle stepI 6.,',and 4in inaiinertas hereinbefore explained will. malte y, and V- break: the {engageinent i between, thehpawl '25 .andratchet 24 according to the weight of the pot as deterf mined by .the ,amount of ,metal Htherein. If the temperatureshouldfbeeoine too low v(below AIl-f-.clby reasonv of al shortage. of gas .or froingany cause, thenqtlie shrinking of .the mercury and .attendant `droppingof he inner float, 11'? ywillpermit, thecontact. shoulf dei` 115 to -fall.in.fiont of vthe, lower vstep@ when the potnextiinoif'es forward, and upon tlie return ofthe pot the pawl would be held disengagedfroni the Arate-het 24 regardless` ofr'any. depletion l ofthe pot contents, thus kpreventingthe feeding. of cold metal to the already cooled pot contents. Usually the condition of the vproduct would inform anopeifator .of they extremelyy lowered teniperature; butiin anyVV event as the. pot becaine lighter the arin92 wouldiilti'rnately be retained in' a *forward position Aas a result of the lightened pot and inmannerbefo-re eX plained would notifythe operator of the -vab'- normal condition. Thehorizontal measurenient of the lower step o may besuch Vthat the arin 92 will be .operative beforethe step a, beconiesfnon-eieetive ducato anextrenie forward position ofthe pot.

If the metal inthe pot became tooV hot (above 5509 F then the shoulder'lliwouldx rise to a position in front of the upper step the ,pot contents. Buti if the temperature were not sufficiently reduced when or before, the metal rose to the safe height of the ring 91 then Athe .mercury bulb 119 lwould become a float, risingl with the molten nietal until a shoulder 122y on the arm 123 re-. inained inA positionito engage the lower step a uponr return of the pot from the mold, whereupon vthe pawl 25 would be prevented from engaging theratcliet 211, stopping` the feed. To this end` the mercury container tube 120is secured in the. arni .123, which is loosely mounted on the hinge pin .78 asa pivot about which the bulb 119 rises or falls. Ordinarily the teinperaturel of the, metaly would have been sutli'ciently'regulated before the inetal reached the.ring 91'. In any event the feed will be discontinued at this point, as explained. andunless the product is affected by the high temperature, production could continue .until the receding lmetal* permitted the shoulder 122 to fall belowthe lower step a, wliereuponunless the shoulder 115 had also dropped in frontof. the middle step Y), additionalcold metal would'be fed to the-pot. 'As an additional precaution for preventinp; the' temperature remaining high for anyconsiderablelength of tinie, I provide inea-iis for autoiiiaticallj;vr reducing fand subsequently` 'iestoi'ingthe 0'as (or electric current) supply, `as follows Thegfloat arni 123 Yis couiiterbalaiiced to an .extei'it' by a pivoted arinI 1211L mounted onthe jacketof the melting; pot by means of a pivotscrew The rear end of.tliis ai'in. 121 bea-rs beneath a pin 126 in the-float ai-in 12S. ,As the bulb llfl'iisesY with theA nietal in the pot theforward and heavier' end of them-111124 falls until a pinl26 projectingtherefrom liesin front Otan exteiisioni127 integra-l with a valve 12S in thegas-siipply pipe 129, whereupon when the pot inoiies forward the pin 126 engages the valve projection 12.7 vand partially closes the valve opening, reducingv the gas supply. Meantime another pin 130 will have dropped below a valve-closing projection 131, preventing the valve being` closed until' the float arni 123 has dro ined with. the receding metal; when tlieinetal has reeeuedsutliciently the pin 130 will return to a position in front ofthe valveprojecF tion 131 andk upon a subsequent forwardmovement of the pot the valve `128v willkbe again opened, increasing' the .gas supply to normal. lVhen itliesouree of heat is electric current instead of gas a. suitable; electric Vswitch may displace the valve128. Y lne-lider that an operator may be'iliot'id Dit theex llO treme ten'iperature condition calling for a reduction of the heat supply, l provide as follows: A catch-block 132 is secured to the machine frame 13B by means of screws 1311-., the arm 12st is provided with a hook portion 135; when the forward end of the arm 124: drops diie to high inet-al at a high temperature, the hoolr will, upon a subsequent forward movement of the pot, en the catchblock 132, thus retaining the pot in a forward position. The arm 92 will then function in the manner hereinbefore described, and cause the machine to stop or the bell 95 to be sounded. This device may be used either in conjunction with or in lieu of the special valve 128. ylhe proper weight of the float for causing it to rise with a maximum height of metal may be regulated by the total amount of mercury in both the outer container 119 and inner container 117. The total weight having' been determined, a sufficient proportion of the mercury is then placed within the inner tiibe 117 to cause this meml'ier to retain the shoulder 115 at normal height under noi'nial temperature conditions. in opening 136 in the inner float permits the mercury to be readily transferred from one to the other container until the proper proportions are determined. Depressing the inner tube toward the bottom of the bulb 119 will cause the mercuiwT to rise around. the inner tube until a portion enters the opening 186. if too much mercury enters, the tube may be removed after first removing the lever 111i and a portion of the mercury poured back into the outer container. rllhe levei' 114i is suitably counterbalanced and limited in its movement by an extension 1141 beyond the pivot 18T. A loose cap 139 serves to guide and center the inner tube 117, and a tapered plug 140 is the direct support for the lever 114. The bulb 119 may be provided with an aluminum jacket 138 as an aid in overcoming any tendency of the molten instal to cling to the bulb. The outer tube 120 is threaded into the arm 123, as a provision for regulating the extent of immersion of the bulb 119 in the molten metal when at medium height. The indicated relative measurements and proportions of the mercury containers and associated parts may be liberally construed in order to effect the desired results;

A modification of the pot-contact principle of feed control .is shown in Fig. a. ln this form of control the auxiliary potbalancing spring may be omitted and the pot permitted to return the usual entire distance to a position of rest against its cam. rlhe outer mercury container is partly immersed in the moltenmetal when the pot is sufficiently full, and when the metal recedes to a point below the bulb the resultant falling of the float within the mercury container will cause the shoulder 115 to drop below a vertical shoulder (Z on the sling 11G', thus permitting the pawl 25 to engage the ratchet 24, and releasing the replenishing metal;

the resultant rise of the metal in the pot will thereupon again immerse the mercury container, causing the float 117 to rise and the shoulder 115 to remain in front of the vertical shoulder CZ, stop-ping the feed. This may be considered an improvement over types of floats immersed directly in the molten metal for regulating the height thereof, but does not suffice for regulating the temperature since it is not effective to advance or retard the feed. 'ln this construction the position of the mercury-floated shoulder 115 and not the 'reight of the pot registers and controls the height of the molten metal.

'When the feeder is in raised position foi' use as a slug feeder, an extension 7 3 of the sling 73 provides for the contact with the pin '572. A suliicient number of the slugs 13 will engage the threads of the feed screws 1, 2 to cause most of the mass of slugs to move forward as the screws rotate; such slugs as are not thus carried forward will be collected in front of an end portion of the follower 15. This end portion is centered between the feed screws in engagement therewith, while other engaging members 15 enter the screw threads on the outsidel thereof. lllhen the follower has been carried forward and stopped against the front brackets 10 the rotation of the screws will thereby be resisted, the spring 31 will stretch and the operating lever will be expanded, permitting the rod 10 to enter in front. of the shoulder 41, and the bell S) will be sounded, all in the manner hereinbefore described, thus notifying the operator or attendant that the feeder is nearly empty of slugs.

For use with the feeder as a preheating or melting' feeder employing large ingots 1G, the follower 15 is provid-ed with a lip 16" which engages a notch 1G cast in the ingot. The follower will thus either retard or push the ingot according to the. inclination of the feeder relative to the horizontal. The premelting device now to be described will operate in similar manner whether the feeder contains small pigs as shown in Fig. 1 or large ingots as in. Fig. 8, but ordinarily, in use with the small pigs, it would be employed merely to heat and not necessary melt the pigs. ln this connection it may be noted that feed metal in any shape would be pre-heated to a limited extent by reason of the front of the feeder terminating above K the melting pot and receiving the heat radiated therefrom.

lhere gas is employed as the source of heat the preheater may be suspende-d from an extension 141 of the usual supply pipe 129, the usual gas governor (not shown) receiving gas from a tube 142 after the has .passed "through the special valve 128 hereinbefore described. The preheater is designed to 'be `readily turned intefor ont of operative position by a :quarter 'turn thereof on ythe supply pipe extension .141.v

To .this end the valve holder 143 isi-provided with a. stop pin144 which is stoppcdagainst a stopping pin 145 :in the .pipe 1141 when the preheater is in non-operative positionfas in Fig. 3. Anextension ofthe valve1l46 carries a torch 147 incommunication with the-.valve chamber 148. The valve extension is also provi-ded with a limiting stem V149 .which is stopped against fa pin 150 in the valve holder lwhen the valve is fully open.. r'll-he opening .and closing yof the valve is 'oontrolled by an end .gate 1:51 which .is dependent on the forward movement of the feed metal for its valve-'opening .mo-vement, and upon the melting away of the metal for its valveclosing movement. The metal is advanced by the feed screws .in the manner previously described, .its movement com'- mencing when a sufficiently depleted .pot causes the pawl 25 to engage the ratchet 24; but the rota-tion of the feed screws is stopped when a -rod 1152, controlled-by the end gate 151, contacts `Vwifthan extensionl-f of the pawl 25. A movement of the feed metal suilicient to thus cause vthe vdisengage ment of the pawl 25 is more than suflicient to fully open the valve 146, the additional movement of the gate after *the valve is open being' permitted by compression of a spring' 154. The gate has securedr't'hereto a -rela'-V tively rigi-d bracket 155, to which .a'relatively movable member :156 is normally fheld .in parallel alinement by means of the spring 154 and spring rod 157. An abutment screw 158 carried by the movable member 156 serves to open the. valve asthe gateswings outward, and the upper abutment screw 159 carried by the rigid Vmember i155 partially closes the valve when the metal :melts away, permitting the vgate to close; 'but after the valve is fully open the 'gate continue-s to move forward until an appreciable space 160 intervenes between that fsteni 149 and the closing screw 159; hence the valve .will remain fully open for a time after fthe-metal commences to melt, before the valveeclosing screw 159 again engages the stem 149, whereupon the valve will be gradually closed and the torch 147 gradually moved downward and away from the feed metal until` melting ceases. Thereafter, whatever flame remains will merely keep the end gate. and adjacent feed metal warmed. 1n order to fully extinguish the torch flame the preheater mustv be turned tenori-operative position,fout of engagement with the abutment l screws 158, 159, when the valve may be entirelyclosed by turning the torch downward untl vit .-is stopped against a stop .pin i161. The yend gate -is provided with corrugations orflutes a rod 182 secured tto thefend gate 180.

162 to 'rpermit `the spreading of the .torch flame across the end lof the ,feed rmetal.

In 'case velectric current 'displaces gas .as the source :of heat Afor 'the `melt-ing ;pot, the preheater vmay v be of lelectric type .fas villustrated in Fig. 11. VAsr shown, the resistor wire or ribbon 163 yis 'confined 4between itwo plates 164, 165 of the endgate. The advance ofthe feed'fmetal causes a terminal scr-ew 166 to Contact ywith la `terminal vbloc'k A167.; thereafter the end gai-te continues Yto ino-ve forward until -atimilng yspace exists between vthe insulating arm 168 and a conductor spring 169 which remains in engagement with lthe abutment'screw 170 in the insulating bracket 171; a conductor wire 17 2connect's the screw 17 0 to the'resistor wire'163 andthe circuit is complet-ed through a terminal plug 173, the wire 174,1binding screw and return wire 176. `The circuit havingbee-n made, melting will continue :until the feed metal has been reduced sufficiently to permit `the abutment screw 170 to force. Ythe `conductor spring 169 against -the arm .168, whereupon the vterminal screw 166 will :be moved, breaking .the circuit. The tendency of the spring 15.4 to keep the lbracket 171 and abut-ment 178 in alinement also serves to keep the end gate against vthe feed vmetal .as melting proceeds. A' bracket Y177 supports the `heating un-it from a convenient fadjacentpart of the Smachine frame, and the heater 'mayberendered inoperative by Awithdrawing the terminal plu'g173. The yfeeder mayfbe freed for raising or yremoval vby turning the 'circuit-closing abutment Y178 lto a non-interfering'position about the spring-rod v157.

lWh'en tlnevfeeder isemployed melting feeder the potilid may bev leftope-mgperm-itting the 'metal toV drip 'directly into the Crucible. f

In Fig. 1-2 isfillustrated the application of the balanced-pot lprinciple of feed-'control toa form lo-fffeeoler disclosed in my U. S. Lette-rsPatent No. 1,21'5,677,;issued February 3, 1917. In this .form of feeder the pigs of metal are stored in the inclined channel 17 9 against anlen'd gate 189. At oppositesid-esl of the feeder a releasing'lever 181vengage ,f dog .183 @makes and breaks the connection between fa 4cam-controlled operating lever 184 and the releasinglever 181,-"the dog intermittently engaging a catch-block 3185 supportedV in the :floor V186 ofthe releasing lever. Then this catcherblock is engaged by the 'dog the operating lever and releasing lever 'are ineffect Vone centrally-pivoted leverand the rotation of thefca-m 35 :will cause the for# ward llever 181 vto be tilted about the 'pivot 187, freeing lthe horizontally-hunggate and permitting .the lforward lpig of metal .to slide from I,the ehannel1`79 to an apron 188 and thence intothe-.melting pot, all inf-man- .er similar to that described: insaid letters patent. When the cani 35 completes its rotation a spring (not shown) restores the releasing lever, shoulders 190 thereon engaging extensions 191 of the end gate and insuring the reengag-ement of the gate by the releasing lever. A. cross-bar 189 meanwhile enters in front of the unreleased pigs and prevents their escape. As described '1n Said Letters Patent No. 1,215,677 connect-ion between the dog 188 and catch-block 185 '1s made and broken by means of a float falling and rising with the metal in the melting pot. 1n the present disclosure ,l combine the weighing principle with the float principle of feed control, so that in the event of either device failing to function properly, the' other will insure proper response to the rising and falling of the metal in the pot. ii control lever 192 is pivoted on a pin 193 secured in the supportingl frame 194. At its rear end this lever supports the dog 183, a spring 195 serving tu normally hold the dog out of engagement with the catch-block 185; but when the metal in the pot becomes low and the pot as a censequence remains forward, the contact pin i2 will free the control lever` 192 and the weight of the vlioat 190 will overcome the spring 195, permitting the dog 183 to engage the catch-block 185, whereupon the releasing lever will be tilted and a pig released as explained. To this end the float rod is pivoted on a pin 197 and has an ei;- tension 198 shape-d to bear upon the control lever 192 with increasing force as the metal in the pot becomes low. vFailure of the pot to remain forward when the metal is low will prevent the float from functioning, coutact of the pin 72 with the control rod overcoming the tendency of the lioat to depress the control rod; and any tendency of the float to drop regardless of a sufficiently full pot will not4 of itself cause a pig to be released, for the .sufficiently weighted pot would overcome such tendency. For ez;- anrplc: if a fouled plunger 89 should hold the pot slightly forward as hereinbefore explained, the float could function nevertheless and a pig would be released with the depletion of the pot; and if a newly-delivered pig should fail to become immers-ed sulficiently to cause the float to respond prior to a succeeding rotation of the cani 85, the pig could nevertheless weight the pot sufficiently to prevent a second pig being immediately released. Any failure of the pot to return the distance indicated by its weight will of itself tend to prevent a second pigl immediately following a partially immersed pig, due to the fact that the metal rises with the pot about its pivot 52; hence a forward position of the pot will have the partial effect of a newly immersed pig, and tend to prevent a premature dropping of the float. A resilient connection 199 prevents damage to the parts in the event that the pot is moved while the metal is solidified.

A modification of the combined float and pot-contact principles of feed control is shown in Fig. 13. In this showing the dog 183 will drop of its own weight when permitted to do so by reason of the float falling with the receding metal; but if the float should fall regardless of the pot being sufficiently heavy with metal, then the sufficiently weighted pot would nevertheless prevent the dog 188 engaging the catchblock 185; and if the pot should remain forward regardless of its being sudiciently heavy, the float could nevertheless hold the pawl 183 out of engagement with the catchblock 185. To this end, the extension 198 of the float rod is beneath the control lever 193, and the spring 195 is omitted.

The application of the combined float and pot-contact principles of feed control to the forni of feeder particularly described herein is illustrated in Fig. 14. ln this illustration it will be noted that the slino' 200 is connec-ted to the pawl 25 as before described, except that the connecting rod Telf engages the pawl below its pivot- 29. The float 196 is suspended from the slingl 200, the float rod 201 being formed with various shoulders and depressions for resiliently engaging a staple 202 and pin 208, so that the floatmay be .readily removed when the feeder is in raised position as a slug feeder. When so raised the arm 77 may be readjusted about the pot hinge pin 78 to provide the necessary contact either with the sling or an auxiliary lever 20srlhis auxiliary lever engages a shoulder 205 of the sling 200 and when the pot is suhiciently heavy with molten metal the engagement of the contact pin T 2 with the lever 2011 will keep the pawl 25 out of engagement with the ratchet 24. Failure of the pot to settle bach to the extent indicated by the weight of its contents will not of itself permit the pawl 25 to engage the ratchet 2li, for the proper height of the metal will retain the float at a corresponding height and thus hold the pawl 25 inoperative; also, any tendency of the noat to fail to rise with newly-fed metal will not of itself cause the pawl 25 to become or remain operative, for the weight of the pot will overcome any such tendency of the float; and, as before explained, if the pot remains forward regardless of its containing su'liicient metal, the metal will be correspondingly high relative to the float pivot 11, thus tending to raise the float .regardless of a limited immersion of newly delivered metal. Although shown and described in combination with the potcontact principle of feed-control, it will be apparent that the float principle will of itself serve to control the feed and therefore adapts the feeder to use with melting pots which are not adapted to the contact princitemperature regulator.

I-Iaving described vmy .invention land lits use, I claim as new and desire vto'secure by Letters Patent:

l. In a crucible charger., in con'ib'ination., a melting pot to ybe replenished, an inclined semi-.gravity support for pigs of .replenishing 'metal for said pot, and a pair of coacting conveyer screws inclined with said suppo lt toward said melting pot for conveying the pigs of feed metal thereto, successive turns of the threads of said screws engaging successive pigs of metal so that said `pigs of metal may be either advanced and released individually into the melting pot or retard-ed against gravity regardless of theinclination of their support.

2. In a -cru'cible charger, in combination, -a trough .for supporting a loosely-spread mass of slugs of type metal for deposit in a melting pot, and a pair `of co-acting conveyer screws within said trou-gh, successive turns of the threads of said screws engaging land independently7 supporting successive divisions of the mass of slugs in said .trougl'i in order that the mass of slugs may remain evenly spread while bein-g advanced toward a nd into the melting pot.

f3. A combination as specified in claim 1Q, .including also a follower in engagement with `and capable of being' advanced by the feed screws, said follower serving to coliect and-advance Aslugs remaining out of direct control of said screws, and being capable also of resisting the rotation of the feed screws when the slug-container is approximately cleared of slugs, for the purpose specified. i

4. In .a Crucible charger, in con'ibination, a pair of coacting conveyer lscrews between which an ingot of crucible-replenishingmetal may be confined, a support for said ingot, a melter 'for melting Vsaid ingot, a Crucible below said melter capable of receiving the metal melted from said ingot, a follower in engagement with said screws and with said ingot, means for rotating said screws to canse said ingot to beadvanced under control yof said follower and toward said melter intermittently Vaccording ltothe amount of metal in said crucible, and coacting means for rendering said melter intermittently operative or non-operative in time with the intermittent movement of said ingot on its support under control of the feed screws and said follower.

5. A combination as specified in :claim el, characterized by the fact that the follower recited therein is capable of causing resistance to the rotation of the feedscrews when said ingot has been fully advanced 'on its support, such resistance serving to notify fau operator that the ingot has been `fully advanced, in the manner andfor the purpose specified.

G. Ina crucible charger, in combination, a support for feed metal, means for advancing the feed metal on its support, a Crucible for receiving the feed metal, anda pit inthe cover of the vcrncible into and 'through which the feed metal may drop from its support, said pit lhaving hinged side and end walls capable of offering limited lresistance to said feed metal in order to check the momentum thereof when it enters the Crucible, and serving to close the ,potopening following the entry of feed metal.

7. A combination as specified .in Vclaim k(5, characterized by the fact that the walls of the Crucible-closing pit recited therein are v hinged as la unit to the Crucible cover in order that the crucible may remain openor closed `at will. Y

8. In a vCrucible ycharger7 in rcon'ibinatiion,A a reciprocating melting pot, feed screws for advancing feed metal toward fand into said melting pot, a pawl and ratchet forrotating said feed screws, means for imparting reciprocating movement to'said pawl regardless of its engagement with or disengagement from said ratchet, a resilient support for causing said `melting pot to reciprocate varying distances according to the quantity of lmolten metall-herein, and interconnecting means between said pawl and lsaid pot, for causing the reciprocations of said p-awl Sto'efiect the advance .of said feed metal intermittently with limited reciprocations fof said pot as determined by its ydepletion of molten metal, said interconnecting means serving also to prevent the advance of the feed metal when a full supply of molten metal causes said pot to reciprocate an extreme distance.

"9. A combination as specifi-ed in claim 8, including also a resilient lever for operating the pawl and ratchet recited'therein, means for operating said lever and causing the expansion v.thereof when .the feed screws :are unduly resisted, a bell associatesL with said lever', ine-ans whereby said bell is sounded when said lever is expanded, and inea-ns whereby said lever is rendered inoperative relative to its function following the expansion thereof.

10. In a Crucible charger for .linotype machines. a combination as specified in claimS, including also a reciprocating'elevator arm common to linotyp'e machines, a resilient lever nfor operating the aforementioned pawl and ratchet, said lever being capable vof e5:- pansion when unduly resisted in vits acti-on, and interconnecting means 'between said resilient vlever and said elevator/arm whereby Cil said arm is hindered in its movement when said lever is expanded, as and for the purpose specified.

11. In a crucible charger for linotype machines, a combination as specified in claim 8, including also an extension from the melting pot recited therein, an elevator arm common to linotype machines and mf'ivable in time with the reciprecations of said meltingl pot, and interengaging means between said elevator arm and said pot extension whereby said arm isl hindered in its movement when the reciproeations of said melting pot are unduly limited in extent, as and for the purposes specified.

12. In a crucible charger for linotype machines a combination as specified in claim S. including also an extension from the melting potrecited therein, a bell thereon, an elcvator arm common to linotype machines and movable in time with the reciprocations of said melting pot, and a device on said arm for causing said bell to besonnded when the reciprocations of said melting pot are unduly limited in extent, as and for the purposes set forth.

13. In a pot charger, a crucible, means for advancing feed metal to said crucible, a primary lever for operating said advancing means, a pivoted secondary lever normally functioning as part of said prin'iary lever, a cam-roller on said secondary lever, a. cam for engaging said roller and thereby imparting movement to said primary lever, and a resilient connection between said pnimary lever and said secondary lever, whereby said cam-roller is permitted to move about its pivot to a non-obstructing position when said cam is turned in a contrary direction.

11i. In a crucible charger, in combination, feed screws for supplying feed metal to a melting pot, an inverted channel for sapporting the feed metal, brackets on each end of said inverted channel for supporting said screws, fore and aft supporting shafts for said inverted channel, a channeled brace connecting said supporting shafts, open latches in said inverted channel for permitting its engagement with and disengagement from said Supporting shafts without removing said channeled brace, and a prop pivoted on said forward shaft and retained Within said channeled brace when said inverted channel is in engagement with its forward support, said prop being capable of spacing` said inverted channel away from its forward support in order to change the position of the crucible charger according to the character of feed metal available'for use therewith.

15. A combination as specified in claim 14, including also a pawl and ratchet for rotating the feed screws recited therein, an operating lever for said pawl, and a sling and connecting rod for making and breaking the recieve connection between said pawl and ratchet, said operating lever, pawl, sling and connecting rod being supported in the aforementioned inverted channel and movable therewith to and from a raised or lowered position as determined by the character of feed metal available for use.

16. In a crucible charger, in combination, a reciprocatingmelting pot, means for advancing feed metal thereto, means for causing said melting pot to reciprocate varyiiig distances according to the weight of its con tents, and means whereby reciprocations thereof associated with a depleted melting pot will canse said advancing means to become operative to effect the replenishment of the melting pot.

17. In a crucible charger, in combination, a. reciprocating melting pot, feed metal for replenishing said melt-ing pot, premelting means for adding said feed metal to the pot contents in melted condition, means for causing said melting pot to reciprocate varying distances according to the weight of its contents, and means whereby reciprocations of the melting pot associated with a depleted condition thereof will canse said premelting means to become effective for replenish'ing said melting pot.

18. In a crucible charger, in combination, a melting pot to be replenished,feed metal for replenishing said inciting pot, means for advancing said feed metal intermittently to said pot, a premelter for melting .the feed metal into the pot, and means whereby the intermittent movement of said feed metal will canse said preheater to become operative and non-operative in time with the advance of the feed metal to the pot.

19. In a crucible charger, in combination, a melting pot to be replenished, a mercury container therein, a mereury-controlled floatvithin said mercury container, means for automatically supplying feed metal to said melting pot, and means whereby the varying height of the molten metal in the pot will cause said merenry-controlled doat to render said feed-metal supplying means effective or non-eective according to the depleted or replenished condition of the melting pot.

20. In a crucible charger, in combination, a melting pot to be replenished, means for supplying feed material thereto, a mercurycontrolled float for rendering said feed-sup ply means intermittently operative or nonoperative according to the depleted or replenished condition of the melting pot, and means co-operating with said iioat whereby the action of said feed-supply means may be retarded or advanced according to the temperature of the pot contents, for the purpose of controlling the temperature of the pot contents.

Cil

Q1. In a Crucible Charger, in combination, a melting pot, feed screws for advancing feed metal toward and into said melting pot, a pavl and ratchet for rotating said feed screws, means for imparting reciprocating movement to said paWl regardless of its en-. gagement with or disengagement frein said ratchet, a float supported by the molten metal Within the pot, and interconnect-ing means between said float and said paWl for Causing said feed screws to be rotated intermittently according to the depleted or replenished condition of the melting pot.

In a crucible Charger for typecasting machines, a reciprocating melting pot, means for advancing feed metal to the pot, a hitand-miss device actuating by the typecasting machine for rendering said feed-'metal advancing means operative or non-operative according to the depleted or replenished condition of the melting pot, means controlled by the reciprocations of the pot for rendering said lhit-and-miss device effective only When the pot is depleted, and a float controlled by the level of the molten metal Within the pot for likewise rendering said hit-and-miss 'device effective only when the pot is depleted, said float means and the means controlled by the reciprocations of the pot serving as a check one upon the other for insuring the replenishing of the pot regardless of the failure of either means to respond to the fluctuations of the moltenA metal Within the pot.

23. In a Crucible Charger, in combination, a reciprocating melting pot, mechanism for advancing` feed metal to the pot, and a hitand-miss device for rendering the feedmetal advancing mechanism alternately operative and nonnoperative for the purpose of maintaining' the molten metal in the pot at a predetermined level, said hit-and-miss device being controlled by the reciprocations of the melting pot.

24. In a crucible Charger, in combination, a melting pot to be replenished, apparatus foiI supplying replenishing material to said pot and a pit formed Within the lid of the melting pot and having self-Closing movable Walls capable of easing the replenishing material to the Crucible, said pit being movable as a unit in and out of the pot opening for the purpose of providing access to the Crucible.

In a Crucible Charger, in combination, a reciprocating melting pot,` feed metal therefor, means for maintaining the molten met-al in the pot at a predetermined level under normal temperature conditions and at a 'different level under abnormal temperature conditions, and co-acting means whereby the movement of the reciprocating pot will serve to reduce the source of heat when the pot contents is at a maximum height and retains an abnormal temperature.

26. In a Crucible charger for slug-Casting machines, a reciprocating melting pot, means for supplying feed metal thereto at intervals suflicing to maintain the pot contents at a predetermined level When the pot Contents is at a normal temperature, means for automatically raising the level of the pot Contents for maintaining a normal temperature thereof, means for hindering the reciprocations of `the melting pot when the pot Contents are abnormally high and at an abnormal temperature, and means whereby the hindered reciprocations of the pot Will serve to notify an operator of the combination of abnormal conditions.

27. In a Crucible Charger, in Combination, a melting pot, means for supplying feed metal thereto at intervals suificing to maintain the Contents thereof at a predetermined level when at a normar temperature, means for increasing the supply 0f feed metal when the temperature of the pot contents is above normal, and means for stopping the supply of feed metal when the temperature of the pot Contents is below normal.

In testimony whereof I have hereunto affixed my signature this 2nd day of Angust, 1922.

GEORGE E. MARLATT. 

